The X-ray emission of the gamma Cassiopeiae stars

TL;DR

This paper reviews the characteristics, classification, and potential physical mechanisms behind the hard X-ray emissions observed in gamma Cassiopeiae stars, emphasizing their significance among massive stars and exploring magnetic star-disk interactions.

Contribution

It redefines gamma Cas stars based on X-ray properties, discusses their variability, and advocates for magnetic star-disk interactions as the primary X-ray production mechanism.

Findings

Gamma Cas stars emit hard thermal X-rays with specific spectral features.

Approximately 9-13 Galactic B0-1.5e stars are classified as gamma Cas stars.

Magnetic star-disk interactions are the most plausible explanation for their X-ray emission.

Abstract

Long considered as the "odd man out" among X-ray emitting Be stars, \gamma Cas (B0.5e IV) is now recognized as the prototype of a class of stars that emit hard thermal X-rays. Our classification differs from the historical use of the term "gamma Cas stars" defined from optical properties alone. The luminosity output of this class contributes significantly to the hard X-ray production in massive stars in the Galaxy. The gamma Cas stars have light curves showing variability on a few broadly-defined timescales and spectra indicative of an optically thin plasma consisting of one or more hot thermal components. By now 9--13 Galactic \approx B0-1.5e main sequence stars are judged to be members or candidate members of the \gamma Cas class. Conservative criteria for this designation are for a \approxB0-1.5e III-V star to have an X-ray luminosity of 10^{32}--10^{33} ergs s^{-1}, a hot thermal spectrum containing the short wavelength Ly \alpha FeXXV and FeXXVI lines and the fluorescence FeK feature all in emission. If thermality cannot be demonstrated, for example from either the presence of these Ly \alpha lines or curvature of the hard continuum; these are the gamma Cas candidates. We discuss the history of the discovery of the complicated characteristics of the variability in the optical, UV, and X-ray domains, leading to suggestions for the physical cause of the production of hard X-rays. These include scenarios in which matter from the Be star accretes onto a degenerate secondary star and interactions between magnetic fields on the Be star and its decretion disk. The greatest aid to the choice of the causal mechanism is the temporal correlations of X-ray light curves and spectra with diagnostics in the optical and UV wavebands. We show why the magnetic star-disk interaction scenario is the most tenable explanation for the creation of hard X-rays on these stars.